研究生: |
陳致維 Chi-wei Chen |
---|---|
論文名稱: |
考慮碳排放及風電容量佔比之最佳火力機組調度 Optimal Thermal Unit Commitment under CO2 Emission and Wind Power Penetration Consideration |
指導教授: |
張宏展
Hong-Chan Chang |
口試委員: |
吳瑞南
Ruay-Nan Wu 郭政謙 Cheng-Chien Kuo 陳柏宏 Po-Hung Chen |
學位類別: |
碩士 Master |
系所名稱: |
電資學院 - 電機工程系 Department of Electrical Engineering |
論文出版年: | 2011 |
畢業學年度: | 99 |
語文別: | 中文 |
論文頁數: | 87 |
中文關鍵詞: | 機組排程 、備轉容量 、二氧化碳 、粒子群演算法 、蒙地卡羅模擬法 |
外文關鍵詞: | Unit Commitment, Spinning Reserve, CO2, Particle Swarm Optimization, Monte Carlo Simulation |
相關次數: | 點閱:591 下載:10 |
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隨著二氧化碳的排放越來越受國際間的關注,只考慮發電成本最低的系統備轉容量規劃方式已不夠充分,因此,本論文旨在提出考量二氧化碳排放量及再生能源併入時的系統可靠度指標變化下的最佳備轉容量規劃,以供電力調度上的選擇。首先,採用發電成本及碳排放量兩種不同的目標規劃模式,然後以不同的備轉容量值和不同的風電佔比來做機組排程的求解,由於發電排程屬於大型非線性的問題,不利於用一般的數學規劃方式來求解,本文採用具全域搜索能力的粒子群演算法來求解發電排程的問題。另外為了使獲得全域最佳解的機率增高,搭配適當的編碼技術來符合限制條件。其次,依據這些機組排程解,利用蒙地卡羅模擬法中的狀態持續時間取樣法來得出其可靠度評估。此模擬方案的特點在於使決策者能夠在顧及環保、經濟及可靠性因素下擬訂適合的備轉容量值。
最後,以台電公司的27部機組系統進行測試,研究結果顯示本論文所提之模擬規劃方法確實有助於電力業者決定備轉容量值。
With the increasing international concern about carbon dioxide (CO2) emissions, it is no longer adequate to plan spinning reserves taking only the lowest production cost into account. Therefore, the purpose of this thesis was to present an optimal spinning reserve planning scheme considering CO2 emissions and the variations in the system reliability index while incorporating renewable energy in the power dispatch selection. First, we introduced two different objective scheduling modes of production costs and CO2 emissions, and then solved the unit commitment problem in different spinning reserve values and wind penetrations. Owing to the large-scale non-linear programming problem of generation scheduling, the issues were hard to solve by a general mathematical programming method. This study applied a particle swarm algorithm with a global search capability to the generation scheduling problem. Furthermore, in order to obtain a higher probability of the global optimum, the simulation process used appropriate coding techniques to meet the constraints. Secondly, we utilized the state duration sampling of the Monte Carlo simulation to acquire the reliability assessment of these unit commitment solutions. The salient feature of the simulation strategy was that the decision-maker could make a proper spinning reserve level involving environmental, economic and reliability factors simultaneously.
Finally, taking the 27-unit system of the Tai-power as a test example, the simulation results showed that the proposed approach could indeed assist the power industry in setting the value of the spinning reserve.
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